Hematopoietic Serine Proteases from the Mast Cell Chymase and Tryptase Loci - a Functional and Evolutionary Analysis

Abstract: Mast cells are key effector cells in allergic and inflammatory diseases. However, their primary role is most likely in host defence against parasitic and bacterial infections. Mast cells are a particularly rich source of serine proteases. These proteases belong to the chymase or the tryptase family, which are encoded from the mast cell chymase and the multigene tryptase loci, respectively. To better understand the biological functions and the molecular evolution of these enzymes we have studied the organisation of these two loci in species ranging from fish to human. We show that the mast cell chymase locus has evolved from a single founder gene to a complex locus during the past 200 Myr of mammalian evolution. Forty-five fish candidate genes for hematopoietic serine proteases were also identified. However, in phylogenetic analyses none of them grouped with individual branches holding mammalian mast cell chymase locus genes, indicating an independent parallel evolution in fish.Studies of the evolution of the multigene tryptase locus showed that this locus has been highly conserved between marsupials and eutherians. However, no genes belonging to the individual subfamilies identified in eutherians could be identified in fish, amphibians or in birds, which also here indicates parallel evolution.To study the evolution of specific cleavage specificities associated with these proteases, the extended cleavage specificity of opossum α-chymase was determined and found to be nearly identical to human mast cell chymase and the major mouse mast cell chymase mMCP-4. This indicates a strong pressure to maintain this specificity during mammalian evolution.Basophils are rare blood cells with functions similar to mast cells that when mature almost completely lack mRNA. To study the proteome and to primarily characterize the granule protein content of basophils, an in vitro purification protocol was developed to obtain transcriptionally active umbilical cord blood-derived basophil precursors.